NACE MR0175- CRA Written Exam My Reading 1 (Part 2 of 2b) 2017 Nov 21th
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Oil Exploration & Production
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Oil Exploration & Production
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Oil Exploration & Production
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闭门练功
Charlie Chong/ Fion Zhang
Oil Exploration & Production
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闭门练功
NACE MR0175 Written Exam
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Annex A
(normative) Environmental cracking-resistant CRAs and other alloys (including Table A.1 — Guidance on the use of the materials selection tables)
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A9 Charlie Chong/ Fion Zhang
A.9 Precipitation-hardened nickel-based alloys (identified as individual alloys) A.9.1 Materials chemical compositions Table D.9 lists the chemical compositions of the precipitation-hardened nickel-based alloys shown in Table A.31 to Table A.37.
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A.9.2 Environmental and materials limits for the uses of precipitationhardened nickel-based alloys Table A.31 to Table A.33 give the environmental and materials limits for the uses for any equipment or component of precipitation-hardened nickel-based alloys divided into groups I, II, and III, respectively. Table A.31 — Environmental and materials limits for precipitation-hardened nickelbased alloys (I) used for any equipment or component
Table A.32 — Environmental and materials limits for precipitation-hardened nickelbased alloys (II) used for any equipment or component Table A.33 — Environmental and materials limits for precipitation-hardened nickelbased alloys (III) used for any equipment or component Table A.34 — Environmental and materials limits for precipitation-hardened nickelbased alloys used for wellhead and christmas tree components (excluding bodies and bonnets) and valve and choke components (excluding bodies and bonnets)
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Table A.35 — Environmental and materials limits for precipitation-hardened nickelbased alloys used as non-pressure containing internal valve, pressure regulator, and level controller components and miscellaneous equipment Table A.36 — Environmental and materials limits for precipitation-hardened nickelbased alloys used as springs Table A.37 — Environmental and materials limits for precipitation-hardened nickelbased alloys used in gas lift service
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Table A.31 — Environmental and materials limits for precipitationhardened nickel-based alloys (I) used for any equipment or component
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These materials shall also comply with the following: a) wrought UNS N07031 shall be in either of the following conditions: 1. solution-annealed to a maximum hardness of 35 HRC; 2. solution-annealed and aged at 760 째C to 871 째C (1 400 째F to 1 600 째F) for a maximum of 4 h to a maximum hardness of 40 HRC. b) wrought UNS N07048, wrought UNS N07773, and wrought UNS N09777 shall have a maximum hardness of 40 HRC and shall be in the solutionannealed and aged condition; c) wrought UNS N07924 shall be in the solution-annealed and aged condition at a maximum hardness of 35 HRC; d) cast UNS N09925 shall be in the solution-annealed and aged condition at a maximum hardness of 35 HRC; e) cast UNS N07718 shall be in the solution-annealed and aged condition at a maximum hardness of 40 HRC. a
No data submitted
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Table A.32 — Environmental and materials limits for precipitationhardened nickel-based alloys (II) used for any equipment or component
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These materials shall also comply with the following: a) wrought UNS N07718 shall be in any one of the following conditions: 1. solution-annealed to a maximum hardness of 35 HRC; 2. hot-worked to a maximum hardness of 35 HRC; 3. hot-worked and aged to a maximum hardness of 35 HRC; 4. solution-annealed and aged to a maximum hardness of 40 HRC. b) wrought UNS N09925 shall be in any one of the following conditions: 1. cold-worked to a maximum hardness of 35 HRC; 2. solution-annealed to a maximum hardness of 35 HRC; 3. solution-annealed and aged to a maximum hardness of 38 HRC; 4. cold-worked and aged to a maximum hardness of 40 HRC; 5. hot-finished and aged to a maximum hardness of 40 HRC. c) number-1 wrought UNS N09935 shall be in the solution annealed and aged condition to a maximum hardness of 34 HRC; d) number-1 wrought UNS N09945 shall be in the solution annealed and aged condition to a maximum hardness of 42 HRC; a
No data submitted to ascertain whether these materials are acceptable for service in the presence of elemental sulfur in the environment.
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Table A.33 — Environmental and materials limits for precipitationhardened nickel-based alloys (III) used for any equipment or component
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These materials shall also comply with the following: a) UNS N07626, totally dense hot-compacted by a powder metallurgy process (HIP??) , shall have a maximum hardness of 40 HRC and a maximum tensile strength of 1 380 MPa (200 ksi) and shall be either: 1. solution-annealed [927 °C (1 700 °F) minimum] and aged [538 °C to 816 °C (1 000 °F to 1 500 °F)], or 2. direct-aged [538 °C to 816 °C (1 000 °F to 1 500 °F)]. b) wrought UNS N07716 and wrought UNS N07725 shall have a maximum hardness of HRC 43 and shall be in the solution annealed and aged condition; c) wrought UNS N07716 and wrought UNS N07725 in the solution-annealed and aged condition can also be used at a maximum hardness of HRC 44 in the absence of elemental sulfur and subject to the other environmental limits shown for the maximum temperature of 204 °C (400 °F); d) wrought UNS N07022 shall have a maximum hardness of HRC 39 in the annealed and aged condition.
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Table A.34 — Environmental and materials limits for precipitationhardened nickel-based alloys used for wellhead and christmas tree components (excluding bodies and bonnets) and valve and choke components (excluding bodies and bonnets)
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Table A.35 — Environmental and materials limits for precipitationhardened nickel-based alloys used as non-pressure containing internal valve, pressure regulator, and level controller components and miscellaneous equipment For these applications, these materials shall also comply with the following: a) wrought UNS N07750 shall have a maximum hardness of 35 HRC and shall be either 1. solution-annealed and aged, 2. solution-annealed, 3. hot-worked, or 4. hot-worked and aged. b) wrought UNS N05500 shall have a maximum hardness of 35 HRC and shall be either 1. hot-worked and age-hardened, 2. solution-annealed, or 3. solution-annealed and age-hardened. a
No data submitted to ascertain whether these materials are acceptable for service in the presence of elemental sulfur in the environment. Charlie Chong/ Fion Zhang
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Table A.36 — Environmental and materials limits for precipitationhardened nickel-based alloys used as springs For this application these materials shall also comply with the following: ď Ž ď Ž
UNS N07750 springs shall be in the cold-worked and age-hardened condition and shall have a maximum hardness of 50 HRC; UNS N07090 can be used for springs for compressor valves in the coldworked and age-hardened condition with a maximum hardness of 50 HRC.
a
No data submitted to ascertain whether these materials are acceptable for service in the presence of elemental sulfur in the environment.
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Table A.37 — Environmental and materials limits for precipitationhardened nickel-based alloys used in gas lift service
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A.9.3 Welding of precipitation-hardened nickel-based alloys of this materials group The requirements for the cracking-resistance properties of welds shall apply (see 6.2.2). ď ° The hardness of the base metal after welding shall not exceed the maximum hardness allowed for the base metal and ď ° the hardness of the weld metal shall not exceed the maximum hardness limit of the respective metal for the weld alloy.
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A.10 Cobalt-based alloys (identified as individual alloys) A.10.1 Materials chemical compositions Table D.10 lists the chemical compositions of the cobalt-based alloys shown in Table A.38 to Table A.40.
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A.10.2 Environmental and materials limits for the uses of cobalt-based alloys Table A.38 — Environmental and materials limits for cobalt-based alloys used for any equipment or component Table A.39 — Environmental and materials limits for cobalt-based alloys used as springs Table A.40 — Environmental and materials limits for cobalt-based alloys used as diaphragms, pressure measuring devices, and pressure seals
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A.10.3 Welding of cobalt-based alloys of this materials group The requirements for the cracking-resistance properties of welds shall apply (see 6.2.2). The hardness of the base metal after welding shall not exceed the maximum hardness allowed for the base metal and the hardness of the weld metal shall not exceed the maximum hardness limit of the respective metal for the weld alloy.
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Table A.38 — Environmental and materials limits for cobalt-based alloys used for any equipment or component
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Table A.39 — Environmental and materials limits for cobalt-based alloys used as springs
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Table A.40 — Environmental and materials limits for cobalt-based alloys used as diaphragms, pressure measuring devices, and pressure seals
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A11 Charlie Chong/ Fion Zhang
A.11 Titanium and tantalum (individual alloys) A.11.1 Materials chemical compositions A.11.1.1 Titanium alloys Table D.11 lists the chemical compositions of the titanium alloys shown in Table A.41. A.11.1.2 Tantalum alloys Table D.12 lists the chemical compositions of the tantalum alloys shown in Table A.42.
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A.11.2 Environmental and materials limits for the uses of titanium and tantalum alloys
Table A.41 — Environmental and materials limits for titanium used for any equipment or component Table A.42 — Environmental and materials limits for tantalum used for any equipment or component
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Table A.41 — Environmental and materials limits for titanium used for any equipment or component
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These materials shall also comply with the following: a) UNS R50250 and R50400 shall have a maximum hardness of 100 HRB; b) UNS R56260 shall have a maximum hardness of 45 HRC and shall be in one of the three following conditions: 1) annealed; 2) solution-annealed; 3) solution-annealed and aged. c) UNS R53400 shall be in the annealed condition. Heat treatment shall be annealing at (774 ± 14) °C [(1 425 ± 25) °F] for 2 h followed by aircooling. Maximum hardness shall be 92 HRB; d) UNS R56323 shall be in the annealed condition and shall have a maximum hardness of 32 HRC; e) wrought UNS R56403 shall be in the annealed condition and shall have a maximum hardness of 36 HRC; f) UNS R56404 shall be in the annealed condition and shall have a maximum hardness of 35 HRC; g) UNS R58640 shall have a maximum hardness of 42 HRC.
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Specific guidelines shall be followed for successful applications of each titanium alloy specified in this part of ISO 15156. For example, hydrogen embrittlement of titanium alloys can occur if these alloys are galvanically coupled to certain active metals (e.g. carbon steel) in H2S-containing aqueous media at temperatures greater than 80 °C (176 °F). Some titanium alloys can be susceptible to crevice corrosion and/or SSC in chloride environments. Hardness has not been shown to correlate with susceptibility to SSC/SCC. However, hardness has been included for alloys with high strength to indicate the maximum testing levels at which failure has not occurred.
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Table A.42 — Environmental and materials limits for tantalum used for any equipment or component
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A.11.3 Welding of titanium and tantalum alloys of this materials group The requirements for the cracking-resistance properties of welds shall apply (see 6.2.2). The hardness of the base metal after welding shall not exceed the maximum hardness allowed for the base metal and the hardness of the weld metal shall not exceed the maximum hardness limit of the respective metal for the weld alloy.
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A12 Charlie Chong/ Fion Zhang
A.12 Copper- and aluminium-based alloys (identified as materials types) A.12.1 Copper-based alloys Copper-based alloys have been used without restriction on temperature, pH2S, Cl−, or in situ pH in production environments. NOTE 1 Copper-based alloys can undergo accelerated mass loss corrosion (weight loss corrosion) in sour oil field environments, particularly if oxygen is present. NOTE 2 Some copper-based alloys have shown sensitivity to GHSC. A.12.2 Aluminium-based alloys These materials have been used without restriction on temperature, pH2S, Cl−, or in situ pH in production environments. The user should be aware that mass loss corrosion (weight loss corrosion) of aluminium-based alloys is strongly dependent on environmental pH.
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A13 Charlie Chong/ Fion Zhang
A.13 Cladding, overlays, and wear-resistant alloys A.13.1 Corrosion-resistant claddings, linings and overlays The materials listed and defined in A.2 to A.11 can be used as corrosionresistant claddings, linings, or as weld overlay materials. Unless the user can demonstrate and document the likely long-term inservice integrity of the cladding or overlay as a protective layer, the base material, after application of the cladding or overlay, shall comply with ISO 15156-2 or this part of ISO 15156, as applicable. This may involve the application of heat or stress-relief treatments that can affect the cladding, lining, or overlay properties. Factors that can affect the long-term in-service integrity of a cladding, lining, or overlay include environmental cracking under the intended service conditions, the effects of other corrosion mechanisms, and mechanical damage. Dilution of an overlay during application that can impact on its corrosion resistance or mechanical properties should be considered.
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A.13.2 Wear-resistant alloys A.13.2.1 Wear-resistant alloys used for sintered, cast, or wrought components Environmental cracking resistance of alloys specifically designed to provide wear-resistant components is not specified in ISO 15156 (all parts). No production limits for temperature, pH2S, Cl−, or in situ pH have been established. Some materials used for wear-resistant applications can be brittle. Environmental cracking can occur if these materials are subject to tension. Components made from these materials are normally loaded only in compression.
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A.13.2.2 Hard-facing materials Hard facing may be used. Environmental cracking resistance of alloys or surface layers specifically designed to provide hard facing is not specified in ISO 15156 (all parts). No production limits for temperature, pH2S, Cl−, or in situ pH have been established. Some materials used for hard-facing applications can be brittle. Environmental cracking of the hard facing can occur if these materials are subjected to tension. Unless the user can demonstrate and document the likely long-term inservice integrity of the hardfacing materials, the base material after application of the hard-facing material shall comply with ISO 15156-2 or this part of ISO 15156, as applicable.
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Annex B (normative) Qualification of CRAs for H2S-service by laboratory testing
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B.1 General This Annex specifies minimum requirements for qualifying CRAs for H2S service by laboratory testing. Requirements are given for qualifying resistance to the following cracking mechanisms:
SSC at ambient temperature; SCC at maximum service temperature in the absence of elemental sulfur, S0; HSC of CRAs when galvanically coupled to carbon or low alloy steel, i.e. GHSC.
Supplementary requirements concern a. testing at intermediate temperatures when the distinction between SSC and SCC is unclear, and b. SCC testing in the presence of S0.
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Guidance on the potential for corrosion to cause cracking of CRAs is given in Table B.1. The alloy groups are the same as those used in Annex A. The test requirements of this Annex do not address the possible consequences of sequential exposure to different environments. For example, the consequence of cooling after hydrogen uptake at a higher temperature is not evaluated.
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Table B.1 — Cracking mechanisms that shall be considered for CRA and other alloy groups
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B.2 Uses of laboratory qualifications B.2.1 General An overview of the uses of laboratory qualifications is given in Figure B.1  Š
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Key a. This part of ISO 15156 addresses SSC, SCC, and GHSC of CRAs and other alloys. ISO 15156-2 addresses SSC, HIC, SOHIC, and SZC of carbon and low alloy steels. b. Annex A addresses SSC, SCC, and GHSC of CRAs and other alloys. ISO 15156-2:2015, Annex A addresses SSC of carbon and low alloy steels. c. See final paragraphs of “Introduction” for further information regarding document maintenance. NOTE Flowchart omits qualification by field experience as described in ISO 15156-1. Figure B.1 — Alternatives for alloy selection and laboratory qualification
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B.2.2 Qualification of manufactured products The user of this part of ISO 15156 shall define the qualification requirements for the material in accordance with ISO 15156-1 and Annex B. This definition shall include the application of the following: a. general requirements (see ISO 15156-1:2015, Clause 5); b. evaluation and definition of service conditions (see ISO 15156-1:2015, Clause 6); c. material description and documentation (see ISO 15156-1:2015, 8.1); d. requirements for qualification based upon laboratory testing (see ISO 15156-1:2015, 8.3); e. report of the method of qualification (see ISO 15156-1:2015, Clause 9). Appropriate “test batches� and sampling requirements shall be defined having regard to the nature of the product, the method of manufacture, testing required by the manufacturing specification, and the required qualification(s) (see Table B.1).
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Samples shall be tested in accordance with Annex B for each cracking mechanism to be qualified. A minimum of three specimens shall be tested per test batch. The test batch shall be qualified if all specimens satisfy the test acceptance criteria. Retesting is permitted in accordance with the following. If a single specimen fails to meet the acceptance criteria, the cause shall be investigated. If the source material conforms to the manufacturing specification, two further specimens may be tested. These shall be taken from the same source as the failed specimen. If both satisfy the acceptance criteria, the test batch shall be considered qualified. Further retests shall require the purchaser’s agreement.
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Testing of manufactured products may be carried out at any time after manufacture and before exposure to H2S service. Before the products are placed in H2S service, the equipment user shall review the qualification and verify that it satisfies the defined qualification requirements. Products with a qualification that has been verified by the equipment user may be placed into H2S service.
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B.2.3 Qualification of a defined production route A defined production route may be qualified for the production of qualified material. A qualified production route may be followed to avoid order release testing for H2S cracking resistance. A materials supplier may propose to a materials purchaser that a qualified production route be used to produce qualified materials. The qualified production route may be used if the materials supplier and materials purchaser agree to its use. A qualified production route may be used to produce qualified material for more than one materials user. To qualify a production route, the material supplier shall demonstrate that a defined production route is capable of consistently manufacturing material that satisfies the applicable qualification test requirements of Annex B.
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The qualification of a production route requires all of the following: a. definition of the production route in a written quality plan that identifies the manufacturing location(s), all manufacturing operations, and the manufacturing controls required to maintain the qualification; b. initial testing of products produced on the defined production route in accordance with B.2.2 and verifying they satisfy the acceptance criteria; c. periodic testing to confirm that the product continues to have the required resistance to cracking in H2S service. The frequency of “periodic� testing shall also be defined in the quality plan and shall be acceptable to the purchaser. A record of such tests shall be available to the purchaser; d. retaining and collating the reports of these tests and making them available to material purchasers and/or equipment users. A material purchaser may agree additional quality control requirements with the manufacturer. The accuracy of the quality plan may be verified by site inspection by an interested party. Changes to a production route that fall outside the limits of its written quality plan require qualification of a new route in accordance with a), b), c), and d) above.
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ď ° initial testing of products produced on the defined production route in accordance with B.2.2 and verifying they satisfy the acceptance criteria; ď ° periodic testing to confirm that the product continues to have the required resistance to cracking in H2S service. Charlie Chong/ Fion Zhang
B.2.4 Use of laboratory testing as a basis for proposing additions and changes to Annex A Changes to Annex A may be proposed (see Introduction). Proposals for changes shall be documented in accordance with ISO 15156-1. They shall also be subject to the following additional requirements. Representative samples of CRAs and other alloys for qualification by laboratory testing shall be selected in accordance with ISO 15156-1. Material representing a minimum of three separately processed heats shall be tested for resistance to cracking in accordance with B.3. Test requirements shall be established by reference to the appropriate materials group in Table B.1.
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B.2.3 Qualification of a defined production route 3 Separate Process Heats Material representing a minimum of three separately processed heats shall be tested for resistance to cracking in accordance with B.3. Test requirements shall be established by reference to the appropriate materials group in Table B.1.
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B.2.3 Qualification of a defined production route 3 Separate Process Heats Material representing a minimum of three separately processed heats shall be tested for resistance to cracking in accordance with B.3. Test requirements shall be established by reference to the appropriate materials group in Table B.1.
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B.2.3 Qualification of a defined production route 3 Separate Process Heats Material representing a minimum of three separately processed heats shall be tested for resistance to cracking in accordance with B.3. Test requirements shall be established by reference to the appropriate materials group in Table B.1.
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B.2.3 Qualification of a defined production route 3 Separate Process Heats Material representing a minimum of three separately processed heats shall be tested for resistance to cracking in accordance with B.3. Test requirements shall be established by reference to the appropriate materials group in Table B.1.
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B.2.3 Qualification of a defined production route 3 Separate Process Heats Material representing a minimum of three separately processed heats shall be tested for resistance to cracking in accordance with B.3. Test requirements shall be established by reference to the appropriate materials group in Table B.1.
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ď ° Tests shall be performed for the primary cracking mechanisms listed in Table B.1. ď ° Tests shall also be performed for the secondary cracking mechanisms listed in Table B.1; otherwise, the justification for their omission shall be included in the test report. For other alloys not covered by Table B.1, the choice of qualification tests used shall be justified and documented. Sufficient data shall be provided to allow the members of ISO/TC 67 to assess the material and decide on the suitability of the material for inclusion into this part of ISO 15156, by amendment or revision, in accordance with the ISO/IEC Directives, Part 1.
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3 types of testing 1. Qualification of manufactured products 2. Qualification of a defined production route 3. Pproposing additions and changes to Annex A
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B.3 General requirements for tests B.3.1 Test method descriptions The test requirements are based on NACE TM0177 and EFC Publication 17. • •
TM0177-2016, Laboratory Testing of Metals for Resistance to Sulfide Stress Cracking and Stress Corrosion Cracking in H2S Environments European Federation of Corrosion Publications NUMBER 17 Second Edition A Working Report on Corrosion Resistant Alloys for 0il and Gas Production: Guidance on General Requirements and Test Methods for H2S Service
These documents shall be consulted for details of test procedures. When necessary, suppliers, purchasers, and equipment users may agree variations to these procedures. Such variations shall be documented.
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B.3.2 Materials The materials tested shall be selected in accordance with the requirements found in ISO 15156-1:2015, 8.3.2. In addition, consideration shall be given to the following: a. the cracking mechanism for which testing is required (see Table B.1); b. the testing of appropriately aged samples of alloys that can age in service, particularly HSC testing of downhole materials that can be subject to ageing in service (“well ageing�); c. the directional properties of alloys because cold-worked alloys may be anisotropic with respect to yield strength and for some alloys and products, the susceptibility to cracking varies with the direction of the applied tensile stress and consequent orientation of the crack plane. 8.3.2 Sampling of materials for laboratory testing The method of sampling the material for laboratory testing shall be reviewed and accepted by the equipment user. The test samples shall be representative of the commercial product. For multiple batches of a material produced to a single specification, an assessment shall be made of the properties that influence cracking behaviour in H2S-containing environments; see 8.1. The distributions of these properties shall be considered when selecting samples for testing according to the requirements of ISO 15156-2 and ISO 15156-3. The materials in the metallurgical condition that has the greatest susceptibility to cracking in H2S service shall be used for the selection of the test samples. Materials source, method of preparation and surface condition of samples for testing shall be documented. Charlie Chong/ Fion Zhang
The Directional Properties Of Alloys
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The Directional Properties Of Alloys
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The Directional Properties Of Alloys
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The Directional Properties Of Alloys
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The Directional Properties Of Alloys
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The Directional Properties Of Alloys
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B.3.3 Test methods and specimens Primary test methods use (1) constant load, (2) sustained load (proof-ring), or (3) constant total strain (constant displacement) loading of smooth test specimens. Uniaxial tensile (UT) tests, four-point bend (FPB) tests, and C-ring (CR) tests may be performed with the above loading arrangements. Generally, constant load tests using UT specimens are the preferred method of testing homogeneous materials. Test specimens shall be selected to suit the product form being tested and the required direction of the applied stress. ď ° A minimum of three specimens shall be taken from each component tested.
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UT specimens may be taken from welded joints in accordance with EFC Publication Number 17, Figure 8.1. Other specimens taken from welded joints may be tested with weld profiles as intended for service. When double (back-to-back) FPB specimens are used (in accordance with EFC Publication Number 17, Figure 8.2a, or similar), uncracked specimens shall be disqualified as invalid if the opposing specimen cracks.
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Fig. 8.1 Designation of tensile specimens taken from welded samples. W: Weld metal; H: Heat affected zone; T: Transverse to weld.
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Fig. 8.2 Schematic illustration of 4-point bend specimens and jigs (based on ISO 7539-2:1989). (a) DOUBLE BENT BEAM CONFIGURATION LOADED BY STUDS. (Alternative to welded configurations shown in ASTM 39 and ISO 7539-2.)
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Fig. 8.2 Schematic illustration of 4-point bend specimens and jigs (based on ISO 7539-2:1989). (b) FOUR-POINT BEND SPECIMEN: STRESS TRANSVERSE TO WELD.
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Fig. 8.3 Schematic illustration of welded C-ring specimen (based on ISO 7539-5:1989).
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Alternative test methods or specimens may be used when appropriate. The basis and use of such tests shall be documented and agreed with the equipment user. Examples of test methods that may be considered are as follows: ď Ž ď Ž
Fracture mechanics tests, e.g. double cantilever beam (DCB) tests, may be used if cracks are unaffected by branching and remain in the required plane. This normally limits DCB tests to SSC and HSC tests. Tests involving the application of a slow strain rate, e.g. SSRT in accordance with NACE TM0198, interrupted SSRT in accordance with ISO 7539-7 or RSRT in accordance with the method published as NACE CORROSION/97 Paper 58.
Tests may utilize testing of full-size or simulated components when appropriate.
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The Acceptable Test Methods 1. 2. 3. 4. 5.
UT FBT C Ring DCB SSRT/ ISSRT/ RSRT
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The Acceptable Test Methods 1. 2. 3. 4. 5.
UT FBT C Ring DCB fracture mechanic test SSRT/ ISSRT/ RSRT
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B.3.4 Applied test stresses/loads for smooth specimens The yield strengths of CRAs used to derive test stresses shall be determined at the test temperature in accordance with the applicable manufacturing specification. In the absence of an appropriate definition of yield strength in the manufacturing specification, the yield strength shall be taken to mean the 0,2 % proof stress of non-proportional elongation (Rp0,2 as defined in ISO 6892-1) determined at the test temperature. Directional properties shall be considered when selecting test specimens and defining test stresses.
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For welded specimens, the parent metal yield strength shall normally be used to determine test stresses. For dissimilar joints, the lower parent metal yield strength shall normally be used. When design stresses are based on the yield strength of a weld zone that is lower than the yield strength of either adjoining parent metals, the yield strength of the weld zone may be used to determine test stresses. ď ° For constant-load tests and sustained-load (proof-ring) tests, specimens shall be loaded to 90 % of the AYS of the test material at the test temperature. ď ° For constant total strain (deflection) tests, specimens shall be loaded to 100% of the AYS of the test material at the test temperature. NOTE Constant total strain (deflection) tests might not be suitable for materials that can relax by creep when under load. Lower applied stresses can be appropriate for qualifying materials for specific applications. The use and basis of such tests shall be agreed with the purchaser and documented. Charlie Chong/ Fion Zhang
Constant Total Strain For constant total strain (deflection) tests, specimens shall be loaded to 100% of the AYS of the test material at the test temperature. NOTE Constant total strain (deflection) tests might not be suitable for materials that can relax by creep when under load.
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B.3.5 SSC/SCC test environments B.3.5.1 General The following environmental test variables shall be controlled and recorded: pH2S; pCO2; temperature; test solution pH, the means of acidification, and pH control (all pH measurements shall be recorded); test solution formulation or analysis; elemental sulfur, S0, additions; galvanic coupling of dissimilar metals (the area ratio and coupled alloy type shall be recorded). In all cases, the pH2S, chloride, and S0 concentrations shall be at least as severe as those of the intended application. The maximum pH reached during testing shall be no greater than the pH of the intended application.
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Elememntal Sulfur
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Elememntal Sulfur
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Elememntal Sulfur
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PCO2
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PH2S/ PCO2
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In all cases, the pH2S, chloride, and S0 concentrations shall be at least as severe as those of the intended application. The maximum pH reached during testing shall be no greater than the pH of the intended application.
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It can be necessary to use more than one test environment to achieve qualification for a particular service. The following test environments may be used eitherďźš ď ° to simulate intended service conditions or ď ° to simulate a nominated condition when intended applications are insufficiently defined. Use can be made of nominated test conditions to provide information on the environmental limits within which a CRA or other alloy is resistant to cracking if no specific application is foreseen. Table E.1 may be used to define the test environments for the standard tests for SSC and GHSC (identified as level II and level III, respectively). For type 1 environments (see B.3.5.2), Table E.1 also provides a number of nominated sets of conditions (for temperature, pCO2, pH2S, and chloride Clconcentration) that may be considered. These are identified as levels IV, V, VI, and VII. Charlie Chong/ Fion Zhang
Table E.1 may be used to define the test environments for the standard tests for SSC and GHSC (identified as level II and level III, respectively). For type 1 environments (see B.3.5.2), Table E.1 also provides a number of nominated sets of conditions (for temperature, pCO2, pH2S, and chloride Clconcentration) that may be considered. These are identified as levels IV, V, VI, and VII. Note: SSC GHSC
Level II Level III
as levels IV, V, VI, and VII ????
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Table E.1 — Test conditions
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Table E.1 — Test conditions
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Table E.1 — Test conditions ? Level I Test conditions defined and documented by the user/ 25 ± 3°C Level II Test in accordance with B.4 B.4- SCC Testing Level III Test in accordance with B.4 & B.8 B.4- SCC Testing B.8- GHSC testing with carbon steel couple Level IV/ V/ VI/ VII Nominated sets of conditions
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When using nominated test conditions, all other requirements of this Annex shall be met.
NOTE 1 The nominated sets of conditions are not intended to limit the freedom of the document user to test using other test conditions of their choice. The equipment user should be aware that oxygen contamination of the service environment can influence the cracking resistance of an alloy and should be considered when choosing the test environment. NOTE 2 Reference [15] gives information on the charging of autoclaves.
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B.3.5.2 Service simulation at actual H2S and CO2 partial pressures Type 1 environments In these test environments, the service (in situ) pH is replicated by controlling the parameters that determine pH under field conditions. Test environments shall be established in accordance with the following requirements: a. test limits: the pressure shall be ambient or greater; b. test solution: synthetic produced water that simulates the chloride and bicarbonate concentrations of the intended service. The inclusion of other ions is optional; c. test gas: H2S and CO2 at the same partial pressures as the intended service; (not absolute?) d. pH measurement: pH is determined by reproduction of the intended service conditions. The solution pH shall be determined at ambient temperature and pressure under the test gas or pure CO2 immediately before and after the test. This is to identify changes in the solution that influence the test pH. Any pH change detected at ambient temperature and pressure is indicative of a change at the test temperature and pressure. (?)
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Any pH change detected at ambient temperature and pressure is indicative of a change at the test temperature and pressure. (?)
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B.3.5.3 Service simulation at ambient pressure with natural buffering agent — Type 2 environments In these test environments, the service (in situ) pH is replicated by adjusting the buffer capacity of the test solution using a natural buffer to compensate for the reduced pressure of acid gases in the test. Test environments shall be established in accordance with the following requirements: a. test limits: the pressure shall be ambient, temperature shall be maximum 60 °C and pH shall be 4,5 or greater; b. test solution: distilled or de-ionized water with sodium bicarbonate (NaHCO3) added to achieve the required pH. Chloride shall be added at the concentration of the intended service. If necessary, a liquid reflux shall be provided to prevent loss of water from the solution; c. test gas: H2S at the partial pressure of the intended service and CO2 as the balance of the test gas. The test gas shall be continuously bubbled through the test solution; d. pH control: the solution pH shall be measured at the start of the test, periodically during the test and at the end of the test, adjusting as necessary by adding HCl or NaOH. The variation of the test pH shall not exceed ¹0,2 pH units. Charlie Chong/ Fion Zhang
B.3.5.4 Service simulation at ambient pressure with acetic buffer — Type 3a and Type 3b environments In these test environments, the service (in situ) pH is replicated by adjusting the buffer capacity of the test solution using an artificial buffer and adding HCl to compensate for the reduced pressure of acid gases in the test. Test environments shall be established in accordance with the following requirements: a. test limits: the pressure shall be ambient, the temperature shall be (24 ¹ 3) °C; b. test solution: one of the following test solutions shall be used: 1) for general use (environment 3a), distilled or de-ionized water containing 4 g/l sodium acetate and chloride at the same concentration as the intended service; 2) for super-martensitic stainless steels prone to corrosion in solution for environment 3a (environment 3b), de-ionized water containing 0,4 g/l sodium acetate and chloride at the same concentration as the intended service. HCl shall be added to both solutions to achieve the required pH;
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c. test gas: H2S at the partial pressure of the intended service and CO2 as the balance of the test gas. The test gas shall be continuously bubbled through the test solution; d. pH control: the solution pH shall be measured at the start of the test, periodically during the test and at the end of the test, adjusting as necessary by adding of HCl or NaOH. The variation of the test pH shall not exceed Âą 0,2 pH units.
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B.3.6 Test duration Constant-load, sustained-load, and constant-total-strain tests shall have a minimum duration of 720 h. Tests shall not be interrupted.
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B.3.7 Acceptance criteria and test report Specimens exposed in constant-load, sustained-load, and constant-totalstrain tests shall be assessed in accordance with NACE TM0177, test methods A, and C. No cracks are permissible. Specimens exposed in fracture mechanics and slow strain rate tests shall be assessed as required by the test method. Fracture toughness values shall only be valid for substantially unbranched cracks. Acceptance criteria for fracture toughness tests shall be specified by the equipment user. In all cases, any indication of corrosion causing metal loss including pitting or crevice corrosion shall be reported. NOTE The occurrence of pitting or crevice corrosion outside the stressed section of a specimen can suppress SCC of the specimen. A written test report conforming to the requirements in ISO 15156-1:2015, Clause 9, shall be completed and retained. Charlie Chong/ Fion Zhang
ANSI/NACE TM0177-2016 Section 8: Method A—NACE Standard Tensile Test
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ANSI/NACE TM0177-2016 Section 8: Method A—NACE Standard Tensile Test
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ANSI/NACE TM0177-2016 Section 8: Method A— NACE Standard Tensile Test
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ANSI/NACE TM0177-2016 Section 10: Method C—NACE Standard C-Ring Test
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ANSI/NACE TM0177-2016 Section 10: Method C—NACE Standard C-Ring Test
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B.3.8 Validity of tests Satisfactory test results qualify materials for environmental conditions that are less severe than the test environment.
Users shall determine the validity of tests for individual applications. Environmental everity is decreased by the following at any given temperature:
— a lower pH2S; — a lower chloride concentration; — a higher pH; — the absence of S0.
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B.4 SSC testing Tests shall be performed in accordance with the general requirements for tests given in B.3. Tests shall normally be performed at (24 ± 3) °C [(75 ± 5) °F] in accordance with NACE TM0177 and/or EFC Publication 17. The test temperature may be at the lowest service temperature if this is above 24 °C (75 °F). The use of a test temperature above 24 °C shall be justified in the test report.
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B.5 SCC testing without S0 Tests shall be performed in accordance with the general requirements of B.3. SCC testing procedures shall be based on NACE TM0177 and/or EFC Publication 17 subject to the following additional requirements, options, and clarifications:
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a. the test temperature shall not be less than the maximum intended service temperature. This can require the use of a pressurized test cell; b. water vapour pressure shall be allowed for in determining gas-phase partial pressures; c. acetic acid and acetates shall not be used for pH control. The solution pH shall be controlled as described in B.3.5.2; d. during initial exposure of specimens to the test environment, the applied load and the environmental conditions shall be controlled so that all test conditions are already established when the test temperature is first attained; e. for constant-total-strain tests, applied stresses shall be verified by measurement; NOTE It is good practice to verify the deflection calculations in many CRA material specifications. f. loading procedures used for constant-total-strain tests shall be shown to achieve a stable stress before specimens are exposed to the test environment.
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B.6 SSC/SCC testing at intermediate temperatures Testing at intermediate temperatures, i.e. between (24 ± 3) °C [(75 ± 5) °F] and the maximum intended service temperature, shall meet the requirements of the equipment user. Testing shall be performed at the specified temperature in accordance with the above requirements for SCC testing. For qualification for inclusion by amendment in A.7, duplex stainless steels shall be tested at:
1. (24 ± 3) °C [(75 ± 5) °F], 2. (90 ± 3) °C [(194 ± 5) °F], and 3. at the maximum intended service temperature of the alloy.
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B.7 SCC testing in the presence of S0 Tests shall be performed in accordance with the previous requirements for SCC tests with the addition that the procedure published in NACE CORROSION/95 Paper 47 shall be implemented for control of S0 additions. The integration of this procedure into CRA test methods is addressed in EFC Publication 17, Appendix S1.
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B.8 GHSC testing with carbon steel couple GHSC tests shall be performed in accordance with the previously stated requirements for SSC testing, subject to the following additional requirements, options, and clarifications: a. the CRA specimen shall be electrically coupled to unalloyed (i.e. carbon) steel that is fully immersed in the test solution. The ratio of the area of the unalloyed steel to the wetted area of the CRA specimen shall be between 0,5 and 1 as required by NACE TM0177. Loading fixtures shall be electrically isolated from the specimen and the coupled steel. For application-specific qualifications, the CRA may be coupled to a sample of the lower alloyed material to which it will be coupled in service. b. the test environment shall be NACE TM0177, Solution A under H2S at a pressure of 100 kPa and at a temperature of (24 ± 3) °C [(75 ± 5) °F]. For application-specific qualifications, SSC test environments described in B.3.5 may be used.
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Annex C (informative) Information that should be supplied for material purchasing
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ISO 15156-1 indicates that cooperation and exchange of information can be necessary between the various users of this part of ISO 15156, e.g. equipment users, purchasers and manufacturers of equipment, purchasers of materials, and manufacturers and suppliers of materials. The following tables can be used to assist this cooperation. The materials purchaser should indicate the required options in Table C.1 and Table C.2. Table C.1 and Table C.2 also suggest designations that may be included in markings of materials to show compliance of individual CRAs or other alloys with this part of ISO 15156. The purchase order details should form part of a material’s documentation to ensure its traceability. Where selection of materials is based upon laboratory testing in accordance with Annex B, traceability documentation should also include the details of the conditions derived from Table C.2 that were applied during testing. Charlie Chong/ Fion Zhang
Table C.1 — Information for material purchase and marking
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a. For use when a purchaser requires a known material that is either listed in Annex A or qualified in accordance with Annex B. The purchaser should indicate the method of qualification below. b. User may insert material type and condition. c. User may insert equipment type for which material is required. d. Indicate which option is required. e. A suggested scheme for designation of listed CRAs to be included in markings of materials is for manufacturers/suppliers to indicate compliance of individual CRAs or other alloys by reference to the materials group clause number, e.g. A.2. For materials qualified to Annex B, the suggested designations are B, B1, B2, B3 (see Table C.2).
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Table C.2 — Additional information for SSC, SCC, and GHSC testing and suggested marking
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a. Indicate which option(s) is (are) required. b. For materials qualified to Annex B, the suggested designations for marking are B, B1, B2, and B3 where B1 is SSC, B2 is SCC, B3 is GHSC, and B indicates that the material has been shown to be resistant to all three cracking mechanisms. c. Test conditions to be appropriate to the service conditions shown in this table (see also B.2 and B.3).
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Annex D (informative) Materials chemical compositions and other information
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D.1 The tables that follow are included for the convenience of the users of this part of ISO 15156 and are based on the SAE — ASTM standard. Users are encouraged to confirm the accuracy of the information shown using the latest edition of this SAE — ASTM standard. D.2 These tables provide a link between the UNS numbers used in the tables of Annex A and the chemical compositions of the alloys to which they refer. Document users are encouraged to consult the SAE — ASTM standard which gives a written description of each alloy, its chemical composition, common trade names, and cross references to other industry specifications. D.3 Alloy acceptability depends upon actual chemical composition within the ranges shown and upon any additional chemical composition, heat treatment, and hardness requirements listed for the alloy in Annex A. Some alloy chemical compositions that comply with the tables do not meet these additional qualification requirements.
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NOTE 1 ISO 15510 [2] provides assistance for the cross-referencing for some UNS numbers to other standards. ISO 13680 [1] provides information relating to materials, their chemical compositions, and their availability for use as casing, tubing, and coupling stock. NOTE 2 Mass fraction, w, is often expressed in US customary units as parts per million by weight and in SI units as milligrams per kilogram. The mass fractions given in the tables of this Annex are expressed as percentage mass fractions, 1 % being equal to 1 g per 100 g. NOTE 3 For Tables D.1, D.2, D.5, D.6, D.7, and D.8, the balance of composition up to 100 % is Fe. NOTE 4 For Tables D.1, D.2, and D.7, the values of (Ni + 2Mo) and/or FPREN have been rounded to whole numbers. They are provided for guidance only.
Charlie Chong/ Fion Zhang
ISO 15156-3:2015(E) Table D.1 — Chemical compositions of some austenitic stainless steels (see A.2 and D.3)
UNS
C
maxa
Cr
Ni
Mn
Si
P
S
Mo
N
maxa
maxa
max
max
max
1,50
2,00
0,04
0,04
—
—
Other
wC wCr wNi wMn wSi wP wS wMo wN
F PREN
Ni + 2Mo
% % % % % % % % %
J92500
J92600
J92800
0,03
0,08 0,03
17,0 to 21,0
8,0 to 12,0
17,0 to 21,0
9,0 to 13,0
18,0 to 8,0 to 21,0 11,0
1,50
1,50
J92843 0,28 to 18,0 to 8,0 to 0,75 to 0,35 21,0 11,0 1,50
J92900
0,08
18,0 to 9,0 to 21,0 12,0
S20200
0,15
17,0 to 19,0
S20910
2,00
0,04
0,04
1,00
0,04
1,50
0,04
1,00 to 1,75
—
Otherb
23 to 30
0,030
—
0,25
—
20 to 22
4 to 6
—
—
16 to 18
1 to 2
0,060
0,030
0,06
20,5 to 11,5 to 4,0 to 23,5 13,5 6,0
1,00
0,040
0,030
S30400
0,08
18,0 to 8,0 to 20,0 10,5
1,00
0,045
0,030
S30500
0,12
S20500 0,12 to 16,0 to 1,00 to 14,0 to 0,25 18,0 1,75 15,5 S30200
S30403
S30800
0,15
17,0 to 19,0
8,0 to 10,0
0,045
0,030
—
24,0 to 19,0 to 26,0 22,0
2,00
1,50
0,045
0,030
—
2,00
1,00
22,0 to 12,0 to 24,0 15,0
S31600
0,08
16,0 to 10,0 to 18,0 14,0
S31635
—
1,00
0,25
0,030 16,0 to 10,0 to 18,0 14,0 0,08
16 to 18
10 to 14
2,00
2,00
2,00
1,00
1,00 1,0
0,045
0,045
0,045
0,045
0,045
0,030
—
2,00
1,00
0,045
0,030
0,030
0,030
—
—
—
0,030
2,0 to 3,0
0,030
2 to 3
0,030
2,0 to 3,0
a
Where a range is shown, it indicates min to max percentage mass fractions.
c
Nb, 0,10 % to 0,30 %; V, 0,10 % to 0,30 %.
e
Minimum value of Nb shall be 10 times the percentage mass fraction of carbon.
b d
—
—
—
—
—
—
—
1,5 to 0,20 to Otherc 3,0 0,40
19,0 to 10,0 to 21,0 12,0
2,00
1,00
0,045
0,030
—
0,08
17,0 to 10,0 to 19,0 13,0
2,00
1,00
0,060
2,0 to 3,0
18,0 to 8,0 to 20,0 12,0
0,20
S31603
2,00
1,00
0,060
0,04
2,0 to 3,0
0,03
S30900 S31000
2,00
1,00
13 to 19
0,04
0,04
1,00
4,0 to 6,0
5,5 to 7,5
24 to 31
—
7,5 to 10,0
16,0 to 3,5 to 18,0 5,5
8 to 12
—
2,00
0,15
17 to 21
—
1,50
S20100
0,04
—
Cu, 0,50 % max; Ti, 0,15 to 0,50 %; W, 1,00 % to 1,75 %; Nb + Ta, 0,30 to 0,70 %.
—
—
—
—
—
18 to 21
24 to 31
17 to 19 29 to 38 17 to 19
18 to 20
8 to 11 10 to 15
13 to 18
4 to 6 15 to 20
8 to 10
8 to 11
—
18 to 20
8 to 12
—
—
19 to 21
10 to 12
—
—
—
—
—
—
0,10
—
17 to 19
10 to 13
—
22 to 24
12 to 15
—
23 to 28
14 to 20
Otherd
23 to 30
—
24 to 26
23 to 28
19 to 22 14 to 20
14 to 20
Minimum value of Ti shall be five times the percentage mass fraction of carbon.
© ISO 2015 – All rights reserved
69
ISO 15156-3:2015(E) Table D.1 (continued) UNS
C
maxa
S31700
S34700
Cr
Ni
Mn
Si
P
S
Mo
N
maxa
maxa
max
max
max
0,08
18,0 to 11,0 to 20,0 15,0
2,00
1,00
0,045
0,030
3,0 to 4,0
—
0,08
17,0 to 19,0
2,00
1,00
0,045
0,030
—
—
Other
wC wCr wNi wMn wSi wP wS wMo wN
F PREN
Ni + 2Mo
% % % % % % % % %
S32100
S38100
0,08
0,08
17,0 to 19,0
9,0 to 12,0
9,0 to 13,0
17,0 to 17,5 to 19,0 18,5
2,00
2,00
1,00
1,50 to 2,50
0,045 0,03
0,030
0,030
—
—
a
Where a range is shown, it indicates min to max percentage mass fractions.
c
Nb, 0,10 % to 0,30 %; V, 0,10 % to 0,30 %.
e
Minimum value of Nb shall be 10 times the percentage mass fraction of carbon.
b d
70
Cu, 0,50 % max; Ti, 0,15 to 0,50 %; W, 1,00 % to 1,75 %; Nb + Ta, 0,30 to 0,70 %.
—
28 to 33
Othere
17 to 19
—
Otherd
—
—
17 to 23
17 to 19
9 to 12
17 to 19
18 to 19
9 to 13
Minimum value of Ti shall be five times the percentage mass fraction of carbon.
© ISO 2015 – All rights reserved
ISO 15156-3:2015(E) Table D.2 — Chemical compositions of some highly-alloyed austenitic stainless steels (see A.3 and D.3) UNS
C
max
S31254
0,020
J93254
0,025
J95370b
Cr
Ni
Mn
Si
P
S
maxa
max
max
max
1,00
0,80
0,030
1,20
1,0
0,45
S31266
0,03
17,5 to 19,7
0,010 6,0 to 6,5
0,030
24 to 17 to 8 to 9 25 18 2,0
0,030
S32200
0,03
1,0
0,5
0,03
S32654
0,02
20,0 to 23,0
21,0 to 24,0
0,50
N08007
0,07
21,0 to 23,0
2,00 to 4,00
N08020c
0,07
N08320
0,05
N08367
0,030
N08904
0,02
N08925
0,02
N08926
0,020
Mo
N
Cu
W
wN
wCu
wW
0,18 to 0,22
0,50 to 1,00
—
0,010 4 to 5 0,7 to 0,8
0 to 0,50
wC wCr wNi wMn wSi wP wS wMo
F PREN
Ni + 2Mo
% % % % % % % % % % % 19,5 to 20,5
19,5 to 20,5 23,0 to 25,0
17,5 to 18,5
0,35 to 0,60
0,50
0,03
0,005
1,50
1,5
—
—
32,0 to 38,0
2,00
1,00
2,5
1,0
20,0 to 22,0
23,5 to 25,5
2,00
19,0 to 21,0
23,0 to 28,0 24,0 to 26,0
24,0 to 26,0
24,0 to 25,0
19,0 to 22,0
27,5 to 30,5
21,0 to 23,0
25,0 to 27,0
19,0 to 21,0
19,0 to 23,0 19,0 to 21,0
0,005 2,5 to 3,5 7,00 to 8,00
2,00 to 3,00
0,045 0,035 2,0 to 3,0 0,04
0,03
1,00
0,04
0,03
2,00
4,0 to 6,0
0,50 to 1,00
30 to 32
0 to 0,10
48 to 54
25 to 28
—
28 to 35
28 to 34
26 to 32
32 to 37
—
0,50 to 3,00
1,00 to 3,00
0,45 to 0,55
0,30 to 0,60
—
—
3,00 to 4,00
—
—
—
—
—
3,00 to 4,00
—
—
—
0,75 max.
—
1,00
0,045 0,035
6,00 to 7,00
0,18 to 0,25 —
1 to 2
—
1,00
0,50 0,5
0,10 to 0,20
0,50 to 1,50
—
2,0
0,045 0,030 6,0 to 7,0 0,03
0,01
4,00 to 5,00
6,0 to 7,0
a
Where a range is shown, it indicates min. to max. percentage mass fractions.
c
wNb shall be eight times wC (% mass fraction) with a maximum of 1 %.
b
0,18 to 0,24
0,035 0,020 5,0 to 7,0
23,0 to 27,0
1,00
0,010 6,0 to 7,0
42 to 45
0,15 to 0,25
0,5 to 1,5
—
42 to 47
46 to 62
54 to 60
30 to 34 31 to 38
35 to 39
25,6 to 30,9
36 to 44
43 to 49
36 to 40
40 to 47
36 to 40
34 to 43
32 to 40
41 to 48
33 to 39
31 to 38
36 to 40
Additional elements, expressed as percentage mass fractions, are Al, 0,01 % max; A, 0,01 % max; B, 0,003 % to 0,007 %; Co, 0,25 % max; Nb, 0,10 % max; Pb, 0,01 % max; Sn, 0,010 % max; Ti, 0,10 % max; and V, 0,10 % max.
© ISO 2015 – All rights reserved
71
ISO 15156-3:2015(E) Table D.3 — Chemical compositions of some solid-solution nickel-based alloys (see A.4 and D.3) UNS
C
max a wC
N06002 N06007
Cr
Ni
Mn
max a max a max a
Mo
Co
w Si
wMo wCo
0,05 20,5 bal.b 17,0 to to to 20,0 0,15 23,0
1,00
1,00
1,0 to 2,0
1,00
8,0 to 10,0
%
%
%
0,05 21,0 bal.b 18,0 to to 23,5 21,0
%
2,0 to 6,0
0,50
N06059 0,010 22,0 bal.b to 24,0
1,5
0,5
N06110
—
0,03 28,0 bal.b 13,0 to to 31,5 17,0
1,5
%
%
5,5 to 7,5
%
0,5 to 2,5
2,5
0,08 12,5 to 14,5
2,5
0,10 15,0 to 16,5
0,3
0,8
Cu
P
S
Ti
max a max a max a max a max a
wMn
N06022 0,015 20,0 bal.b to 22,5
N06030
Si
wFe
%
wCr wNi
Fe
4,0 to 6,0
5,0
wCu %
wP %
wS
w Ti
%
%
Nb + Ta
max a %
—
1,00
—
—
—
0,02
0,02
—
—
1,75 to 2,5 —
0,35
—
—
1,0 to 2,4
0,04
0,02
—
—
—
—
0,30 to 1,50
0,04
0,015 0,005
0,3 to 1,5
2,5 to 3,5
—
—
—
—
1,00 0,030 0,005
—
—
1,25
—
1,25
—
0,1 to 0,4
1,50
—
2,00
—
4,00
—
1,50
—
—
—
—
1,00
—
—
0,69
—
—
—
3,0
—
—
3,15 to 4,15
—
—
—
0,40
—
—
3,0– 4,4
—
—
1,0
—
—
—
—
0,50
0,50
—
—
0,015 0,015 0,40
—
5,0
0,75
8,0 to 10,0
—
—
0,04
—
N06950 0,015 19,0 50,0 15,0 to min to 21,0 20,0
1,00
0,08 15,0 to 17,0 8,0 to 10,0
2,5
0,5
0,04 0,015
—
5,0 to 7,0
—
0,5 to 1,5
0,03 0,003
0,03 23,0 47,0 bal.b to to 26,0 52,0
6,0 to 8,0
0,03
0,03
6,0 to 8,0
5,0
1,5 to 2,5
0,04
0,03
0,03 23,0 48,0 bal.b to to 27,0 56,0
1,0
1,0
1,0
1,0
N06985 0,015 21,0 bal.b 18,0 to to 23,5 21,0
1,00
1,00
N06952
N06975
—
0,70 to 1,20
—
0,03
—
0,03
0,02
a
Where a range is shown, it indicates min to max percentage mass fractions.
c
wNb shall be eight times wC (% mass fraction), with a maximum of 1 %.
b d
72
%
—
5,0
1,00
—
%
—
0,10 20,0 bal.b to 23,0
N06686 0,010 19,0 bal.b to 23,0
—
%
0,03
1,20
N06625
0,2 to 1,0
%
wAl
0,04
—
6,0 to 9,0
wN
1,5 to 2,5
1,00 0,030 0,005
1,0
wW
—
—
0,03 23,0 47,0 bal.b 1,00 to to 26,0 52,0
wV
—
0,09 10,1 to 12,0
N06255
max a
—
1,0
8,00 12,0 to 12,0
Al
—
0,02 20,0 50,0 bal.b to to 23,0 53,0
N06250
—
%
N
0,04 0,030
—
—
W
—
0,50 12,0 to 14,0
0,15 27,0 bal. b to 33,0
V
max a max a max a
wNb+Ta wNb
0,03 19,0 54,0 bal.b 1,50 to to 22,0 60,0
N06060
Nb
0,02 to 0,25
1,5 to 4,0
—
—
0,50
—
0,04
0,6 to 1,5
—
—
—
—
—
—
—
—
—
—
—
—
—
0,50
—
—
1,5
—
—
0,70 to 1,50
“Bal.” is the balance of composition up to 100 %.
Additional elements by mass fraction: w Ta = 0,2 % max and wB = 0,006 % max.
© ISO 2015 – All rights reserved
ISO 15156-3:2015(E) Table D.3 (continued) UNS
C max a wC
N07022d N08007 N08020 N08024 N08026 N08028 N08032
N08042 N08135
Cr
Ni
Mn
Si
max a max a max a
Co
1,8
0,5
0,08 15,5 to 17,4
1,0
0,5
1,00
2,0 to 3,0
—
3,00 to 4,00
0,50 5,00 to 6,70
—
0,4
0,3
4,3
—
0,03 20,5 33,0 bal.b 1,00 to to 23,5 38,0
0,75
4,0 to 5,0
%
0,010 20,0 to 21,4
%
bal.b
%
%
%
wMo wCo %
%
0,07 19,0 27,5 bal.b 1,50 to to 22,0 30,5
1,50 2,00 to 3,00
—
0,03 22,5 35,0 bal.b 1,00 to to 25,0 40,0
0,50
3,5 to 5,0
—
0,03 26,0 29,5 bal.b 2,50 to to 28,0 32,5
1,00
3,0 to 4,0
—
0,07 19,0 32,0 bal.b 2,00 to to 21,0 38,0
0,03 22,0 33,0 bal.b 1,00 to to 26,0 37,2
0,01
22
32
0,03 20,0 40,0 to to 23,0 44,0
bal.b bal.b
1,0
0,5
N08826
0,05 19,5 38,0 bal.b 1,00 to to 23,5 46,0
0,5
%
wS %
0,025 0,015
max a max a max a
wNb+Ta wNb %
%
N
wV
wW
wN
%
%
%
Al max a wAl %
—
—
—
—
0,8
—
0,5
—
—
—
—
—
—
—
3,00 0,045 0,035 to 4,00
—
—
—
—
—
—
—
—
8xC to 1,00c
—
—
—
—
2,00 to 4,00
0,03
—
—
—
—
—
—
—
0,030 0,030
—
—
—
—
—
—
—
0,015 0,002
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
0,2 to 0,8
—
—
—
—
—
—
—
0,50 0,035 0,035 to 1,50
0,6 to 1,4 —
—
1,50
0,03
0,03
—
—
—
—
2,5 to 3,5
—
1,5 to 3,0
—
0,03
0,6 to 1,2
—
—
—
—
—
0,2
—
—
—
—
—
—
4,7 to 5,7
—
0,60 to 1,20 —
—
—
—
3,0 to 4,5
0,17 to 0,25 —
—
—
—
—
—
2,5 to 3,5
1,00
1,00 15,0 to 17,0
2,5
CW12MW 0,12 15,5 bal.b to 17,5
4,5 to 7,5
1,0
1,0
0,08 15,0 to 17,0 16,0 to 18,0
—
1,5 to 3,0
0,03
0,03 0,003
1,5 to 3,0
0,030 0,030
0,6 to 1,2
0,15 to 0,35
2,5 to 4,0
4,0 to 7,0
1,0 to 2,0
0,025 0,010
—
—
—
0,040 0,030
—
—
—
0,35
2,5
—
0,030 0,030
—
—
—
0,35
—
—
0,040 0,030
—
—
—
0,20 to 0,4
a
Where a range is shown, it indicates min to max percentage mass fractions.
c
wNb shall be eight times wC (% mass fraction), with a maximum of 1 %.
d
%
W
0,03
0,08 14,5 bal.b to 16,5
b
w Ti
V
0,03
0,50
1,00
%
wP
max a
Nb
0,70
2,0
4,0 to 7,0
wCu
Nb + Ta
—
1,00
0,02 14,5 bal.b to 16,5
Ti
—
1,00
N10276
S
5,0 to 7,0
0,05 19,5 38,0 22,0 to to min. 23,5 46,0
N08932 0,020 24,0 24,0 bal.b to to 26,0 26,0
P
max a max a max a max a max a
w Si
0,50
N10002
Cu
wMn
N08535 0,030 24,0 29,0 bal.b 1,00 to to 27,0 36,5
N08825
Mo
wFe
%
wCr wNi
Fe
3,0 to 4,5
3,75 to 5,25
“Bal.” is the balance of composition up to 100 %.
Additional elements by mass fraction: w Ta = 0,2 % max and wB = 0,006 % max.
© ISO 2015 – All rights reserved
73
ISO 15156-3:2015(E) Table D.3 (continued) UNS
C
max a
%
CW6MC a
b
wC
Cr
Ni
wCr wNi %
0,06 20,0 to 23,0
%
bal.b
Fe
Mn
Si
max a max a max a
Mo
Co
wMn
w Si
wMo wCo
5,0
1,0
1,0
8,0 to 10,0
%
%
%
P
S
Ti
max a max a max a max a max a
wFe %
Cu
%
—
wCu %
—
wP %
wS %
0,015 0,015
Where a range is shown, it indicates min to max percentage mass fractions.
w Ti %
—
Nb + Ta max a
Nb
—
W
max a max a max a
wNb+Ta wNb %
V
%
3,15 to 4,5
N
Al
max a
%
%
wV
wW
wN
1,0
—
—
%
%
wAl —
“Bal.” is the balance of composition up to 100 %.
c wNb shall be eight times wC (% mass fraction), with a maximum of 1 %. d
74
Additional elements by mass fraction: w Ta = 0,2 % max and wB = 0,006 % max.
© ISO 2015 – All rights reserved
ISO 15156-3:2015(E) Table D.4 — Chemical compositions of some copper nickel alloys (see A.4) UNS
C
Cu
Nia
Fe
Mn
Si
Sa
max
max wCu
wNi
max
max
max
max
0,3
Bal.b
63,0 to 70,0
2,50
2,00
0,50
0,024
N04400 N04405
a
b
wC %
0,30
%
Bal.b
wFe
%
%
63,0 to 70,0
2,5
wMn %
2,0
wSi %
0,50
Where a range is shown, it indicates min to max percentage mass fractions %. Bal. is the balance of composition up to 100 %.
© ISO 2015 – All rights reserved
wS %
0,025 to 0,060
75
ISO 15156-3:2015(E)
UNS
Table D.5 — Chemical compositions of some ferritic stainless steels (see A.5) C
Cr
Ni
Mn
Si
Mo
N
P
S
Other
max wC
wCr
maxa
max
max wSi
wMo
max
max
max
maxa
S40500
0,08
11,5 to 14,5
—
1,00
1,00
—
—
0,040
0,030
Al 0,10 to 0,30
0,12
16,0 to 18,0
—
0,040
—
0,040
%
S40900
0,08
S43400 S44200
S43000 S43600
%
—
0,12
16,0 to 18,0
—
1,00
1,00
0,75 to 1,25
—
0,20
18,0 to 23,0
—
1,00
1,00
—
0,02
19,0 to 21,0
0,60
25,0 to 27,0
0,50
0,12
16,0 to 18,0
S44627
0,010
25,0 to 27,0
0,06
17,5 to 19,5
—
—
1,00
0,010
28,0 to 30,0
—
1,00
1,75 to 2,50
0,025
1,00
—
0,25
1,00
1,00
0,75
0,75
—
0,045
0,045
Ti 6 × C to 0,75b
0,040
0,030
—
0,040
0,040
0,03
0,040
0,030
—
0,030
(Nb + Ta) 5 × C to 0,70b
0,030
[Nb + 0,2 × Ti+ 4(C + N)] 0,8b
0,030
—
0,012
Nb 10(C + N) to 0,8b; Cu 0,30 to 0,60
0,020
Ti 7 × (C + N) minb and 0,20 to 1,00, Cu 0,20
0,40
1,00
1,00
2,50 to 3,50
0,035
0,040
0,030
[Nb + 0,2 × Ti+ 4(C + N)] 0,8b
1,00
1,00
3,60 to 4,20
0,045
0,040
0,030
[Nb + Ta – 6 (C + N)] 0,20 to 1,00b
25,0 to 1,50 to 27,0 3,50
28,0 to 30,0
0,75 to 1,25
%
0,40
28,0 to 30,0
0,030
1,00
1,00
—
%
w
0,50
0,010
S44735
1,00
1,00
%
wS
1,50
24,5 to 3,50 to 26,0 4,50
0,025
1,00
wP
—
0,025
S44660
a
%
—
23,0 to 27,0
S44800
%
1,00
0,20
S44700
%
1,00
S44600
S44635
%
wN
0,50
0,025
S44626
%
wMn
10,5 to 11,75
S44400 S44500
wNi
1,00
0,15
0,30
2,0 to 2,5
0,30
1,00
0,75
0,20 0,20
0,75 to 1,50
0,75 to 1,50
3,50 to 4,50 3,5 to 4,2
3,5 to 4,2
0,04
0,040
0,040
0,030
0,015
0,020
0,020
0,035
0,020
0,020
Where a range is shown, it indicates min to max percentage mass fractions.
0,040 0,025
0,025
0,030
0,020
0,020
—
Nb 0,05 to 0,20, Cu 0,20 [Nb + 0,2 × Ti+ 4(C + N)] 0,8b (C + N) 0,025 Cu 0,15
(C + N) 0,025b, Cu 0,15
b Expresses value(s) for element(s) by reference to the mass fraction of other elements, e.g. Ti 6 × C to 0,75 indicates a value for Ti between six times wC (%) and 0,75 %.
76
© ISO 2015 – All rights reserved
ISO 15156-3:2015(E)
UNS
Table D.6 — Chemical compositions of some martensitic stainless steels (see A.6) Name
S41000
—
S41426
—
S41425
C
Cr
Ni
Mo
Si
P
S
Mn
N
Other
maxa
maxa
maxa
maxa
maxa
maxa
maxa
maxa wMn
wN
maxa
0,15
11,5 to 13,5
—
—
1
0,04
0,03
1
—
—
0,03
11,5 to 13,5
4,5 to 6,5
0,5
0,02
10,5 to 14,0
2,0 to 3,0
wC %
—
0,05
S41427
—
0,03
S41429
—
0,1
S42000
—
0,15 mina
S42500
—
0,08 to 0,2
J91151
—
0,15
S41500
S42400 J91150
J91540
—
—
—
—
wCr %
12 to 15
11,5 to 13,5
wSi
%
%
4 to 7
1,5 to 2
0,5
4,5 to 6,0
1,5 to 2,5
1,5 to 3
0,4 to 0,8
0,005
1,0
—
1,0
0,03
0,03
0,75
0,03
1
0,04
0,03
1
—
—
1
0,02
1
0,2
—
1
—
3,5 to 4,5
0,3 to 0,7
0,3 to 0,6
0,15
11,5 to 14
1
0,5
0,06
11,5 to 14
3,5 to 4,5
0,4 to 1
8 to 10
—
0,9 to 1,1
11,5 to 14
0,15 to 0,22
12 to14
—
L80 13 Cr
0,15 to 0,22
12 to 14
0,15
1
0,5
0,5
0,3 to 0,7
0,15 to 1 —
0,5
0,5 to 1,0
0,03
0,03
0,5 to 1,0
1,5
0,04
0,04
1
1
0,04
0,03
1
1
—
0,03
0,005
0,03
0,5 to 1
—
%
0,02
12,0 to 14,0
1 to 2
%
0,50
0,06
14 to 16
%
0,06 to 0,12
0,6
—
%
w
0,5 to 1,0
0,5 to 1,0
—
%
wS
0,005
3,5 to 5,5
12 to 14
wP
0,02
11,5 to 14,0
420 M —
%
wMo
0,05
—
K90941
wNi
0,04 0,02
0,03 0,02
0,01
0,04
1
0,01
0,25 to 1
0,01
0,25 to 1
0,03
0,3 to 0,6
—
—
—
—
—
Cu 0,3
Ti 0,01 to 0,5; V 0,5
Ti 0,01; V 0,01 to 0,50 b
—
—
—
—
—
—
Cu 0,25
—
Cu 0,25
—
—
a Min indicates minimum percentage mass fraction. Where a range is shown, it indicates min to max percentage mass fractions. b
Additional elements, expressed as percentage mass fractions, are Al, 0,05 % max; B, 0,01 % max; Nb, 0,02 % max; Co, 1,0 % max; Cu, 0,5 % max; Se, 0,01 % max; Sn, 0,02 % max; Ti, 0,15 % to 0,75 %; V, 0,25 % max.
© ISO 2015 – All rights reserved
77
ISO 15156-3:2015(E) Table D.7 — Chemical compositions of some duplex stainless steels (see A.7 and D.3)
UNS
C
Cr
Ni
maxa
maxa
maxa
S31200
0,03
24,0 to 26,0
5,5 to 6,5
2
S31803
0,03
21,0 to 23,0
4,5 to 6,5
2
24,0 to 26,0
5,5 to 8,0
1,5
0,8
24,0 to 26,0
6,0 to 8,0
1,2
0,8
0,5
0,5
0,03
24,0 to 26,0
0,04
20,5 to 22,5
S32550
0,04
24,0 to 27,0
S32760
0,03
24,0 to 26,0
S32520
S32750
S32803b
0,03
0,03
5,5 to 7,5
5,5 to 8,5
26,0 to 3,50 to 29,0 5,20
S39277
0,025 24,0 to 26,0
6,5 to 8,0
J93345
0,08
8,9 to 11,0
S39274 J93370
J93380
J93404
0,03
1
1
0,03
0,2
2
6,0 to 8,0
S32950
S32900
0,75
1,5
28,0 to 29,0
3,0 to 4,0
23,0 to 28,0
2,5 to 5,0
24,0 to 26,0
6,0 to 8,0
N
Cu
W
maxa
maxa
maxa
maxa
1,2 to 2,0
0,14 to 0,20
—
—
0,045
0,03
2,50 to 0,08 to 3,50 0,20
—
—
0,03
0,02
—
0,035
—
0,035
—
0,03
24,0 to 26,0
1
0,03
24,0 to 26,0
6,0 to 8,0
1
1,5
0,20
1,0 to 2,0
0,030
3,0 to 5,0
0,20 to 0,50 to 0,35 3,00
3,0 to 5,0
0,24 to 0,32
1,8 to 2,5
0,025
1,5 to 2,5
—
1
3,0 to 4,0
0,2 to 0,3
0,5 to 1,0
0,5 to 1,0
—
—
—
0,8
1
2,0 to 3,0
0,10 to 0,20 to 0,10 to 0,30 0,80 0,50
2,00 to 0,10 to 4,00 0,25
1
2
2,5 to 3,5
1
0,75
24,5 to 4,75 to 26,5 6,0 6,0 to 8,5
1
1
0,04
20,0 to 27,0
1
1
4,5 to 6,5
0,01
78
maxa maxa
Mo
P
S
F PREN
maxa maxa
% % % % % % % % % % %
S32404
b
Si
wC wCr wNi wMn wSi wMo wN wCu wW wP wS
S31260
a
Mn
0,6
1,00 to 2,00
1,00 to 0,15 to 2,50 0,35
—
—
—
2,50 to 0,24 to 3,50 0,32
0,2 to 0,8
1
1,75 to 2,25
—
2,75 to 3,25
1
3,0 to 4,0
0,2 to 0,3
0,5 to 1,0
0,8
1
3,0 to 4,0
0,23 to 0,33
3,0 to 4,5
0,10 to 0,30
4,0 to 5,0
0,10 to 0,30
1,2 to 2,0
Where a range is shown, it indicates min to max percentage mass fractions. Ratio Nb/(C + N) = 12 min; (C + N) = 0,030 % max; Nb = 0,15 % to 0,50 %.
—
—
—
1,5 to 2,5
0,03
0,03
0,03
34 to 43
0,01
27 to 36
37 to 48
0,02
38 to 48
0,02
0,005
34 to 38
0,035
0,01
32 to 43
0,04
0,03
0,03
0,01
0,04 0,03
—
0,04
0,5 to 1,0
0,03
—
31 to 38
0,02
0,03
0,02
0,80 to 0,025 0,002 1,20 —
30 to 36
0,04
0,04
0,025
—
—
0,025
32 to 44
38 to 46 26 to 35
39 to 47
39 to 46
30 to 34 31 to 47
38 to 46 39 to 47
© ISO 2015 – All rights reserved
ISO 15156-3:2015(E) Table D.8 — Chemical compositions of some precipitation-hardened stainless steels (see A.8) UNS
C
max
%
S15500 0,07 S15700 0,09 S17400 0,07 S45000 0,05 b
Ni
Mn
Si
max
max
24,0 to 27,0
2,00
1,00
1,00
1,00
14,0 to 16,0
3,50 to 5,50
6,50 to 7,75
1,00
1,00
1,00
1,00
14,0 to 16,0
3,00 to 5,00
5,00 to 7,00
1,00
1,00
Mo
Nb
Ti
Cu
Al
P
S
maxa
max
max
B
wC wCr wNi wMn wSi wMo wNb w Ti wCu wAl wP wS wB
S66286 0,08
a
Cr
%
13,5 to 16,0
14,0 to 15,5 15,0 to 17,5
%
%
%
%
1,00 to 1,50 —
2,00 to 3,00 —
%
—
0,15 to 0,45
%
1,90 to 2,35 —
—
—
0,15 to 0,45
—
0,50 8 × Cb to 1,00
—
%
%
—
0,35
2,50 to 4,50
—
—
3,00 to 5,00 1,25 to 1,75
%
%
%
0,040 0,030 0,001 to 0,01
V
wV %
0,10 to 0,50
0,040 0,030
—
0,04
0,03
—
—
—
0,04
0,03
—
—
—
0,030 0,030
—
—
0,75 to 1,50
—
Where a range is shown, it indicates min to max percentage mass fractions. Indicates a minimum value for wNb of eight times the wC (%).
© ISO 2015 – All rights reserved
79
ISO 15156-3:2015(E) Table D.9 — Chemical compositions of some precipitation-hardened nickel base alloys (see A.9) UNS
C
maxa
%
Ni
5,0
0,50
N07022e 0,010 20,0 Bal.b to 21,4
1,8
0,5
N07031
N07048 N07090
20,0 to 23,0
maxa maxa
Mo
Bal.b
0,10
wNi
Mn
wMn wMo
N06625
wCr
Fe
wFe
wC
Cr
%
%
%
%
0,03 to 0,06
22,0 55,0 Bal.b 0,20 to to 23,0 58,0
0,13
18,0 Bal.b to 21,0
0,015 21,0 Bal.b 18,0 to to 21,0 23,5
N07626
0,05
N07716
0,03
N07718
0,08
N07725
0,03
N07773
0,03
20,0 Bal.b to 23,0
1,0
3,0
1,0
6,0
0,50
0,03
N09925
0,03
a
Nb
Cu
Al
Co
N
B
P
S
wSi
wNb
w Ti
wCu
wAl
wCo
wN
wB
8,0 0,50 to 10,0
3,15 to 4,15
0,40
—
0,40
—
—
—
—
—
0,5
0,5
1,0
—
0,006 0,025 0,015
2,10 to 2,60
0,60 to 1,20
1,00 to 1,70
—
—
2,0
—
0,003 0,015 0,015 to 0,007
1,8 to 3,0
—
0,8 to 2,0
15,0 to 21,0
%
%
15,5 0,08 to 17,4
%
1,7 to 2,3
0,20
—
0,10
0,5
—
—
—
5,0 to 7,0
4,50 to 5,50
17,0 50,0 Bal.b 0,35 to to 21,0 55,0
2,8 to 3,3
0,35
4,75 to 5,50
18,0 45,0 Bal.b 1,00 to to 27,0 60,0
2,5 to 5,5
0,50
14,0 34,0 Bal.b 1,00 to to 19,0 42,0
2,5 to 5,5
0,50
19,0 57,0 Bal.b 0,20 to to 22,0 63,0
Ti
maxa maxa maxa maxa maxa maxa maxa maxa maxa maxa
8,0 0,50 to 10,0 7,0 to 9,5
0,20
19,0 55,0 Bal.b 0,35 7,00 0,20 to to to 9,50 22,5 59,0
N07924c 0,020 20,5 52,0 7,0 0,20 to min to 22,5 13,0 N09777
Si
5,5 to 7,0
0,20
19,5 38,0 22,0 1,00 2,50 0,50 to to min to 23,5 46,0 3,50
%
1,5 to 2,0
%
1,5 to 2,2
0,60
0,50
2,75 to 4,00
1,00 to 1,60
—
2,75 to 4,00
1,00 to 1,70
—
%
0,4 to 0,9
%
%
%
wP %
wS %
0,015 0,015
—
0,02
0,01
—
—
—
—
0,40 to 0,80
1,00
0,05
—
0,02 0,015
0,35
—
—
—
0,015 0,01
0,20 to 0,80
1,00
—
0,35
—
—
—
0,015 0,01
0,65 to 1,15
0,30
2,0
—
2,0
—
—
—
0,03
2,75 to 3,5
1,0 to 2,0
1,0 to 4,0
0,75
3,0
0,20
—
0,030 0,005
—
0,35
—
—
—
0,03
0,01
0,50
1,90 to 2,40
1,50 to 3,00
0,10 to 0,50
—
—
—
—
0,03
2,5 to 6,0
0,1
—
0,006 0,015 0,015
0,01
Min indicates minimum percentage mass fraction. Where a range is shown, it indicates min to max percentage mass fractions.
b
“Bal.” is the balance of composition up to 100 %.
e
Additional elements by mass fraction: w Ta = 0,2 % max and wW = 0,8 % max.
c
d
80
Additional elements by mass fraction: wW = 0,5 % max and wMg = 0,005 0 % max. Additional elements by mass fraction: wW = 1,0 % max.
© ISO 2015 – All rights reserved
ISO 15156-3:2015(E) Table D.9 (continued) UNS
C
maxa
%
wC
Cr
Ni
wCr %
wNi %
Fe
Mn
maxa maxa wFe %
N09935d 0,030 19,5 34,0 Bal.b to to 22,0 38,0
%
1,0 1,0
N05500
0,25
N07750
0,08
1,00
a
63,0 2,00 1,50 to 70,0
14,0 70,0 to min 17,0
5,0 to 9,0
wMn wMo
N09945 0,005 19,5 45,0 Bal.b to to to 0,04 23,0 55,0 —
Mo
Si
Nb
Ti
Cu
Al
Co
N
B
P
S
maxa maxa maxa maxa maxa maxa maxa maxa maxa maxa wSi
wNb
w Ti
wCu
wAl
wCo
wN
wB
3,0 to 5,0
0,50
0,20 to 1,0
1,80 to 2,50
1,0 to 2,0
0,50
1,0
—
—
0,025 0,001
—
—
—
0,03
0,03
—
0,50
—
Bal.b
—
—
—
—
0,50
2,30 to 3,15
—
—
0,35 to 0,85
0,01 to 0,7
—
—
—
—
0,01
%
3,0 to 4,0
%
0,5
%
2,5 to 4,5
0,70 to 1,20
%
0,5 to 2,5
2,25 to 2,75
%
1,5 to 3,0
0,5
%
0,40 to 1,00
%
%
%
wP %
wS %
Min indicates minimum percentage mass fraction. Where a range is shown, it indicates min to max percentage mass fractions.
b
“Bal.” is the balance of composition up to 100 %.
e
Additional elements by mass fraction: w Ta = 0,2 % max and wW = 0,8 % max.
c
d
Additional elements by mass fraction: wW = 0,5 % max and wMg = 0,005 0 % max. Additional elements by mass fraction: wW = 1,0 % max.
© ISO 2015 – All rights reserved
81
ISO 15156-3:2015(E) Table D.10 — Chemical compositions of some cobalt-based alloys (see A.10)
UNS
C
maxa
Cr
Ni
Co
Fe
Mn
Si
Mo
maxa maxa maxa
B
P
S
max maxa max
Be
Ti
max maxa
W
wC wCr wNi wCo wFe wMn wSi wMo wB wP wS wBe w Ti wW
%
R30003 0,15
R30004 0,17 to 0,23
%
19,0 to 21,0
19,0 to 21,0
R30035 0,025 19,0 to 21,0 R30159 0,04
R30260c 0,05 R31233 0,02 to 0,10
R30605 0,05 to 0,15
%
15,0 to 16,0
12,0 to 14,0
%
39,0 to 41,0
%
Bal.b
%
1,5 to 2,5
41,0 Bal.b 1,35 to to 44,0 1,80
33,0 Bal.b to 37,0
1,0
0,15
18,0 Bal.b 34,0 8,00 0,20 to to to 20,0 38,0 10,00
%
—
%
6,0 to 8,0
—
2,0 to 2,8
0,15 9,0 to 10,5
0,20
11,7 Bal.b 41,0 9,8 to 0,40 to to 10,4 to 12,3 42,0 1,10
0,20 to 0,60
19,0 9,0 to Bal.b to 11,0 21,0
1,00
6,00 to 8,00 3,70 to 4,30
23,5 7,0 to Bal.b 1,0 to 0,1 to 0,05 4,0 to to 11,0 5,0 1,5 to 6,0 27,5 1,00 3,0
2,0
—
%
%
%
%
%
%
—
—
1,00
—
—
—
—
—
—
0,06
—
—
0,015 0,01
—
1,00
2,3 to 3,3 —
—
0,03
0,02
0,01
—
—
—
—
—
—
0,03
0,02
3,60 to 4,20
—
—
0,20 to 0,30
2,50 to 3,25
—
—
—
13,0 nom.
—
—
—
—
0,80 to 1,20 —
—
Where a range is shown, it indicates min to max percentage mass fractions.
c
Additional elements, expressed as percentage mass fractions, are Nb, 0,1 % max; and Cu, 0,30 % max.
82
wN
—
a
b
%
N
1,0 to 0,03 3,0 to 0,12
“Bal.” is the balance of composition up to 100 %.
© ISO 2015 – All rights reserved
ISO 15156-3:2015(E)
UNS
Al
Table D.11 — Chemical compositions of some titanium alloys (see A.11) V
C
Cr
Fe
H
Mo
N
maxa maxa maxa maxa maxa maxa maxa maxa
Ni
Sn
Zr
maxa maxa
R56260
R53400
—
—
—
—
6
—
—
—
R56323 2,5 to 2,0 to 3,5 3,0
0,10
—
0,20
0,015
—
0,03
—
—
—
0,30
0,015
—
0,03
—
—
—
O 0,25
Bal.b
0,08
—
0,25
0,015
—
0,03
—
—
—
O 0,15, Ru 0,08 to 0,14
Bal.b
0,08
—
—
—
0,30
—
6
0,015 0,2 to 0,4
—
—
2
0,03 0,6 to 0,9
—
4
—
—
0,40 0,0125
—
0,05 0,3 to 0,8
—
—
R56404 5,5 to 3,5 to 6,5 4,5
0,08
—
0,25
0,015
—
0,03
—
—
—
—
6
—
—
4
—
—
—
4
3
8
a
Where a range is shown, it indicates min to max percentage mass fractions.
c
Residuals each 0,1 % max mass fraction, total 0,4 % ma. mass fraction.
“Bal.” is the balance of composition up to 100 %.
UNS
Bal.b
—
0,10
R58640
O 0,18
0,10
R56403 5,5 to 3,5 to 6,75 4,5
—
O 0,25
Bal.b Bal.b
O 0,20, Bal.b Pd 0,04 to 0,08, Residualsc O 0,13, Ru 0,08 to 0,14 —
Table D.12 — Chemical composition of R05200 tantalum alloy (see A.11) C
Co
Fe
Si
Mo
W
Ni
Ti
Other
max
max
max
max
max
max
max
max
max
0,01
0,05
0,01
0,005
0,01
0,03
0,01
0,01
0,015
Bal.b
Bal.b
Ta
wC wCo wFe wSi wMo wW wNi w Ti w
% % % % % % % % %
R05200a
b
maxa
% % % % % % % % % % % %
R50400
a
Ti
wAl wV wC wCr wFe wH wMo wN wNi wSn wZr w
R50250
b
Other
Bal.b
Additional elements, expressed as percentage mass fractions, are Nb, 0,05 % max; H, 0,001 % max; and O, 0,015 % max. “Bal.” is the balance of composition up to 100 %.
© ISO 2015 – All rights reserved
83
Annex E (informative) Nominated sets of test conditions
Charlie Chong/ Fion Zhang
Table E.1 — Test conditions
Charlie Chong/ Fion Zhang
Further Reading https://www.azom.com/article.aspx?ArticleID=470 http://apac.totalmateria.com/page.aspx?ID=CheckArticle&site=KTS&NM=232 http://www.georgesbasement.com/Microstructures/Introduction.htm http://www.paintertoolinc.com/metallurgy.html http://iso-iran.ir/standards/iso/ISO_15156_3_2015_,_Petroleum_and.pdf
Charlie Chong/ Fion Zhang
Charlie Chong/ Fion Zhang
Technical Reading on: CPM/HIP Metallurgy
Charlie Chong/ Fion Zhang
HIP & CPM Technology GENERAL INFORMATIONCPM–Crucible Particle Metallurgy The proprietary Crucible Particle Metallurgy (CPMŽ) process has been used for the commercial production of high speed steels and other high alloy tool steels since 1970. The process lends itself not only to the production of superior quality tool steels, but to the production of higher alloyed grades which cannot be produced by conventional steelmaking. For most applications the CPM process offers many benefits over conventionally ingotcast tool steels.
Charlie Chong/ Fion Zhang
https://www.crucible.com/eselector/general/generalpart3.html
Conventional Steelmaking vs.Particle Metallurgy Processing Conventional steelmaking begins by melting the steel in a large electric arc furnace. It is usually followed by a secondary refining process such as Argon Oxygen Decarburization (AOD). After refining, the molten metal is poured from the furnace into a ladle, and then teemed into ingot molds. Although the steel is very homogeneous in the molten state, as it slowly solidifies in the molds, the alloying elements segregate resulting in a nonuniform as-cast microstructure. In high speed steels and high carbon tool steels, carbides precipitate from the melt and grow to form a coarse intergranular network. Subsequent mill processing is required to break up and refine the microstructure, but the segregation effects are never fully eliminated. The higher the alloy content and the higher the carbon content, the more detrimental are the effects of the segregation on the resultant mechanical properties of the finished steel product.
Charlie Chong/ Fion Zhang
https://www.crucible.com/eselector/general/generalpart3.html
The CPM process also begins with a homogeneous molten bath similar to conventional melting. Instead of being teemed into ingot molds, the molten metal is poured through a small nozzle where high pressure gas bursts the liquid stream into a spray of tiny spherical droplets. These rapidly solidify and collect as powder particles in the bottom of the atomization tower. The powder is relatively spherical in shape and uniform in composition as each particle is essentially a micro-ingot which has solidified so rapidly that segregation has been suppressed. The carbides which precipitate during solidification are extremely fine due to the rapid cooling and the small size of the powder particles. The fine carbide size of CPM steel endures throughout mill processing and remains fine in the finished bar.
Charlie Chong/ Fion Zhang
https://www.crucible.com/eselector/general/generalpart3.html
The powder is screened and loaded into steel containers which are then evacuated and sealed. The sealed containers are hot isostatically pressed (HIP) at temperatures approximately the same as those used for forging. The extremely high pressure used in HIP consolidates the powder by bonding the individual particles into a fully dense compact. The resultant microstructure is homogeneous and fine grained and, in the high carbon grades, exhibits a uniform distribution of tiny carbides. Although CPM steels can be used in the as-HIP condition, the compacts normally undergo the same standard mill processing used for conventionally melted ingots, resulting in improved toughness.
Charlie Chong/ Fion Zhang
https://www.crucible.com/eselector/general/generalpart3.html
CPM Eliminates Segregation Conventionally produced high alloy steels are prone to alloy segregation during solidification. Regardless of the amount of subsequent mill processing, non-uniform clusters of carbides persist as remnants of the as-cast microstructure. This alloy segregation can detrimentally affect tool fabrication and performance. CPM steels are HIP consolidated from tiny powder particles, each having uniform composition and a uniform distribution of fine carbides. Because there is no alloy segregation in the powder particles themselves, there is no alloy segregation in the resultant compact. The uniform distribution of fine carbides also prevents grain growth, so that the resultant microstructure is fine grained.
Charlie Chong/ Fion Zhang
https://www.crucible.com/eselector/general/generalpart3.html
Advantages of CPM For the End User: • Higher Alloy Grades Available • Improved Wear Resistance • Improved Toughness (less chipping) • Consistent Tool Performance • Good Grindability (on resharpening) For the Tool Manufacturer: • Consistent Heat Treat Response • Predictable Size Change on Heat Treat • Excellent, Stable Substrate for Coatings • Excellent Grindability • Improved Machinability (w/sulfur enhancement) • Efficient Wire EDM Cutting
Charlie Chong/ Fion Zhang
https://www.crucible.com/eselector/general/generalpart3.html
Fig. 4.14. Microstructural anisotropy in hot worked HIP tool steels; a: 3.8 % C, 24.5 % Cr, 3.1 % Mo, 9 % V; dark: round MC carbides; grey: M7C3 carbides, larger carbides aligned in deformation direction; scanning electron microscope, back scattered electrons; 300:1; b: 1.55 % C, 4 % Cr, 12 % W, 5 % V, 5 % Co; light microscopy; nital etch; 115:1 a
Charlie Chong/ Fion Zhang
b
https://link.springer.com/chapter/10.1007/10689123_12
These images illustrate the improved microstructure from the HIP process: https://www.kennametal.com/hi/products/engineered-wear-solutions/engineered-components/hot-isostatic-pressing.html?dv=1511254652406
forged duplex steel
Charlie Chong/ Fion Zhang
HIP duplex steel